Method for controlling an industrial robot during lead-through programming of the robot and an industrial robot

1. A method for controlling an industrial robot during lead-through programming, wherein the method includes generating a virtual orientation in space, wherein the space comprises a working range of the robot, and the method includes during lead-through programming of the robot: comparing an orientation of a tool center point (TCP) of the robot with the virtual orientation, and actively controlling the motions of the robot in relation to the virtual orientation when the difference between the orientation of the TCP of the robot and the virtual orientation is less than an offset value (Ao).

2. The method according to claim 1 , wherein the motions of the robot are actively controlled so that the orientation of the TCP of the robot is attracted to or repelled from the virtual orientation when the difference between the orientation of the TCP of the robot and the virtual orientation is less than said offset value (Ao).

3. The method according to claim 1 , wherein the robot is controlled so that the velocity of the robot is reduced when the difference between the orientation of the TCP of the robot and the virtual orientation is less than said offset value (Ao).

4. The method according to claim 1 , wherein the motions of the robot are passively controlled when the difference between the orientation of the TCP of the robot and the virtual orientation is larger than said offset value (Ao).

5. The method according to claim 4 , wherein the robot is controlled so that the robot is fully compliant when the difference between the orientation of the TCP of the robot and the virtual orientation is larger than said offset value (Ao).

6. The method according to claim 1 , wherein the method includes defining a 3D geometrical formula which generates a plurality of virtual orientations regularly occurring in space, and the method includes: comparing the orientation of the TCP of the robot with the respective virtual orientations, and actively controlling the motions of the robot in relation to the closest of the virtual orientations when the difference between the orientation of the TCP of the robot and the closest of the virtual orientations is smaller than said offset value (Ao).

7. The method according to claim 6 , wherein said 3D geometrical formula defines a geometrical pattern in space, and the pattern includes any of points, lines, planes, circles, and spheres.

8. The method according to claim 6 , wherein said 3D geometrical formula generates a plurality of virtual orientations with a fixed angular spacing, and the method includes: comparing the orientation of the TCP of the robot with the virtual orientations, and actively controlling the robot to rotate to the closest virtual orientation when the difference between the orientation of the TCP of the robot and the closest virtual orientation is smaller than said offset value (Ao).

9. An industrial robot comprising a manipulator and a robot controller configured to control the motions of the manipulator, wherein the robot controller is configured during lead-through programming of the robot to compare an orientation of a tool center point (TCP) of the robot with a virtual orientation defined in space, wherein the space comprises a working range of the robot, and to actively control the motions of the robot in relation to the virtual orientation when the difference between the orientation of the TCP of the robot and the virtual orientation is smaller than an offset value (Ao).

10. The industrial robot according to claim 9 , wherein the robot controller is configured to automatically switch between active and passive control of the motions of the robot during lead-through programming of the robot, and the robot controller is configured to passively control the motions of the robot when the difference between the orientation of the TCP of the robot and the virtual orientation is larger than said offset value (Ao).

11. The industrial robot according to claim 9 , wherein the robot controller is configured to control the motions of the robot so that the orientation of the TCP of the robot is attracted to or repelled from the virtual orientation when the difference between the orientation of the TCP of the robot and the virtual orientation is smaller than said offset value (Ao).

12. The industrial robot according to claim 9 , wherein a plurality of virtual orientations regularly occurring in space are defined, and the robot controller is configured to compare the orientation of the TCP of the robot with the respective virtual orientations, and to actively control the motions of the robot in relation to the closest of the virtual orientations when the difference between the orientation of the TCP of the robot and the closest of the virtual orientations is smaller than said offset value (Ao).